# Copyright lowRISC contributors (OpenTitan project).
# Licensed under the Apache License, Version 2.0, see LICENSE for details.
# SPDX-License-Identifier: Apache-2.0
import logging as log
from functools import partial
from typing import Any, Dict, List, Optional, Tuple

from reggen.validate import check_bool, check_int, val_types

from .item import Node, Host, Device, AsyncFifo, Socket1N, SocketM1
from .lib import simplify_addr
from .xbar import Xbar

# val_types = {
#     'd': ["int", "integer (binary 0b, octal 0o, decimal, hex 0x)"],
#     'x': ["xint", "x for undefined otherwise int"],
#     'b': [
#         "bitrange", "bit number as decimal integer, \
#                     or bit-range as decimal integers msb:lsb"
#     ],
#     'l': ["list", "comma separated list enclosed in `[]`"],
#     'ln': ["name list", 'comma separated list enclosed in `[]` of '\
#            'one or more groups that have just name and dscr keys.'\
#            ' e.g. `{ name: "name", desc: "description"}`'],
#     'lnw': ["name list+", 'name list that optionally contains a width'],
#     'lp': ["parameter list", 'parameter list having default value optionally'],
#     'g': ["group", "comma separated group of key:value enclosed in `{}`"],
#     'lg': ["list of group", "comma separated group of key:value enclosed in `{}`"\
#            " the second entry of the list is the sub group format"],
#     's': ["string", "string, typically short"],
#     't': ["text", "string, may be multi-line enclosed in `'''` "\
#           "may use `**bold**`, `*italic*` or `!!Reg` markup"],
#     'T': ["tuple", "tuple enclosed in ()"],
#     'pi': ["python int", "Native Python type int (generated)"],
#     'pb': ["python Bool", "Native Python type Bool (generated)"],
#     'pl': ["python list", "Native Python type list (generated)"],
#     'pe': ["python enum", "Native Python type enum (generated)"]
# }
addrs = {
    'name': 'Address configurations',
    'description':
    '''Device Node address configuration. It contains the base address and the size in bytes.
''',
    'required': {
        'base_addrs':
        ['g', 'Base addresses of the device. It is required for the device'],
        'size_byte':
        ['d', 'Memory space of the device. It is required for the device'],
    },
    'optional': {},
    'added': {}
}

node = {
    'name': 'Node configuration',
    'description': '''
Crossbar node description. It can be host, device, or internal nodes.
''',
    'required': {
        'name': ['s', 'Module instance name'],
        'type': [
            's',
            'Module type: {"host", "device", "async", "socket_1n", "socket_m1"}'
        ],
    },
    'optional': {
        'addr_space': ['s', 'address space for a host port'],
        'clock': ['s', 'main clock of the port'],
        'reset': ['s', 'main reset of the port'],
        'pipeline': ['pb', 'If true, pipeline is added in front of the port'],
        'req_fifo_pass': ['pb',
                          'If true, pipeline fifo has passthrough behavior on req'],
        'rsp_fifo_pass': ['pb',
                          'If true, pipeline fifo has passthrough behavior on rsp'],
        'inst_type': ['s', 'Instance type'],
        'xbar': ['pb', 'If true, the node is connected to another Xbar'],
        'addr_range': ['lg', addrs],
        'stub': ['pb', 'Real node or stub.  Stubs only occupy address ranges']
    },
    'added': {}
}

root = {
    'name': 'Top configuration',
    'description': '''
Crossbar configuration format.
''',
    'required': {
        'name': ['s', 'Name of the crossbar'],
        'clock': [
            's', 'Main clock. Internal components use this clock.'
            ' If not specified, it is assumed to be in main clock domain'
        ],
        'reset': ['s', 'Main reset'],
        'connections': [
            'g',
            "List of edge. Key is host, entry in value list is device"
        ],
        'clock_connections': ['g', 'list of clocks'],
        'nodes': ['lg', node]
    },
    'optional': {
        'type': ['s', 'Indicate Hjson type. "xbar" always if exist'],
        'clock_group': ['s', "Remnant from auto-generation scripts. Ignore."],
        'clock_srcs': ['g', "Remnant from auto-generation scripts. Ignore."],
        'domain': ['s', 'Power domain for the crossbar']
    },
    'added': {
        'reset_connections': [
            'g', "Generated by topgen. Key is the reset signal inside IP"
            " and value is the top reset signal"
        ],
        'addr_spaces': [
            'l', "Generated by topgen. List of address spaces used across all "
            "hosts"
        ],
    }
}

# Minimum device spacing that is checked during validation
# by inspecting the base addresses. Note that the validation
# script also ensures that base addresses are aligned with
# to this granularity.
MIN_DEVICE_SPACING = 0x1000


def check_keys(obj: Dict[Any, Any],
               control: Dict[Any, Any],
               prefix: str = "") -> int:
    """ Check the keys recursively.

    The control parameter is a control group to check obj data structure.
    """
    error = 0

    # Make sure that every key that we expect has actually been passed.
    for k in control['required'].keys() - obj.keys():
        error += 1
        log.error(prefix + " missing required key: " + k)

    # Check every fields' correctness
    for k, v in obj.items():
        checker = ['', '']
        prefix_name = prefix + " " + k

        if k in control["required"]:
            checker = control["required"][k]
        elif k in control["optional"]:
            checker = control["optional"][k]
        elif k in control["added"]:
            log.warning(prefix + " contains generated key " + k)
            checker = control["added"][k]
        else:
            log.warning(prefix + " contains extra key " + k)
            continue

        # Type and value check
        if checker[0] is not None and checker[0] not in val_types:
            log.error(prefix +
                      " field {} is undefined type. Check val_types {}".format(
                          k, checker[0]))
        if checker[0] is None:
            pass
        elif checker[0] == 'lg':
            # List of subgroup
            error += sum(
                map(
                    partial(check_keys, control=checker[1],
                            prefix=prefix_name), obj[k]))
        elif checker[0] == 'g':
            # if second entry isn't string type, call recursively
            if isinstance(checker[1], str):
                log.info(
                    "Skipping {} as no further control group is given".format(
                        prefix_name))
                continue

            error += check_keys(obj=obj[k],
                                control=checker[1],
                                prefix=prefix_name)

        elif checker[0] == 'd':
            int_v, err = check_int(obj[k], prefix_name)
            if err:
                error += 1

        elif checker[0] == 's' or checker[0] == 't':
            # don't care the string
            pass

        elif checker[0] == 'pb':
            b_v, err = check_bool(obj[k], prefix_name)
            if err:
                error += 1

        elif checker[0] == 'l':
            if not isinstance(obj[k], list):
                error += 1
        else:
            log.error(prefix_name +
                      " is not supported in this configuration format")

    return error


def mk_node(typ: str, name: str, clock: str, reset: str) -> Node:
    """Create a graph node with the requested node type.

    This is just a wrapper around the constructors in item.py, and picks the
    right Python class for the textual requested node type.

    `typ` gives the name of the node type. `name` gives the name of the node.
    `clock` and `reset` give the names of the node's clock and reset signals.
    """
    if typ == "host":
        return Host(name, clock, reset)
    if typ == "device":
        return Device(name, clock, reset)
    if typ == "async_fifo":
        return AsyncFifo(name, clock, reset)
    if typ == "socket_1n":
        return Socket1N(1, name, clock, reset)
    if typ == "socket_m1":
        return SocketM1(1, name, clock, reset)

    log.error("Cannot process type {}".format(typ))
    raise


def checkNameExist(name: str, xbar: Xbar) -> bool:
    return name.lower() in [x.name for x in xbar.nodes]


def isOverlap(range1: Tuple[int, int], range2: Tuple[int, int]) -> bool:
    return not (range2[1] < range1[0] or range2[0] > range1[1])


def isNotMinSpacing(range1: Tuple[int, int], range2: Tuple[int, int]) -> bool:
    return not (range2[0] < range1[0] - MIN_DEVICE_SPACING or
                range2[0] >= range1[0] + MIN_DEVICE_SPACING)


def isNotAligned(base: int) -> bool:
    return ((base & (MIN_DEVICE_SPACING - 1)) != 0)


def checkAddressOverlap(addr: Tuple[int, int],
                        ranges: List[Tuple[int, int]]) -> bool:
    result = [(hex(x[0]), hex(x[1])) for x in ranges if isOverlap(x, addr)]
    return len(result) != 0


def checkAddressSpacing(addr: Tuple[int, int],
                        ranges: List[Tuple[int, int]]) -> bool:
    result = [x for x in ranges if isNotMinSpacing(x, addr)]
    return len(result) != 0


# this returns 1 if the size mask overlapps with the address base
def checkBaseSizeOverlap(addr_base: int, size: int) -> int:
    return ((size - 1) & addr_base)


def validate(obj: Dict[Any, Any]) -> Optional[Xbar]:
    xbar = Xbar()
    xbar.name = obj["name"].lower()
    xbar.clock = obj["clock"].lower()
    xbar.reset = obj["reset"].lower()
    addr_ranges: Dict[str, List[Tuple[int, int]]] = {}

    # validate Hjson format first
    hjson_good = validate_hjson(obj)
    if not hjson_good:
        log.error("Hjson structure error")
        return None

    # collection of all clocks and resets of this xbar
    xbar.clocks = [clock for clock in obj["clock_connections"].keys()]
    xbar.resets = [reset for reset in obj["reset_connections"].keys()]

    # Nodes
    for nodeobj in obj["nodes"]:

        if checkNameExist(nodeobj["name"], xbar):
            log.error("Duplicated name: %s" % (nodeobj["name"]))
            raise SystemExit("Duplicated name in the configuration")

        clock = nodeobj["clock"].lower() if "clock" in nodeobj.keys(
        ) else xbar.clock

        reset = nodeobj["reset"].lower() if "reset" in nodeobj.keys(
        ) else xbar.reset

        if clock not in xbar.clocks:
            log.error(
                "Clock %s for module %s does not exist in xbar_%s, check xbar hjson"
                % (clock, nodeobj['name'], obj['name']))
            raise SystemExit("Clock does not exist")

        if reset not in xbar.resets:
            log.error(
                "Reset %s for module %s does not exist in xbar_%s, check xbar hjson"
                % (reset, nodeobj['name'], obj['name']))
            raise SystemExit("Reset does not exist")

        node = mk_node(typ=nodeobj["type"].lower(),
                       name=nodeobj["name"].lower(),
                       clock=clock,
                       reset=reset)

        if isinstance(node, Host):
            node.addr_spaces = {nodeobj["addr_space"]}

        if isinstance(node, Device):
            node.xbar = nodeobj["xbar"]
            node.addr_ranges = {}
            node.addr_spaces = set()

            # Compact the address ranges
            if node.xbar:
                nodeobj["addr_range"] = simplify_addr(nodeobj, obj, nodeobj["addr_space"])

            # Note that only xbar nodes should have multiple ranges for a given
            # ASID, but downstream xbar-to-xbar edges only support one ASID.
            for addr in nodeobj["addr_range"]:
                for asid, base_addr in addr["base_addrs"].items():
                    addr_range = addr_ranges.setdefault(asid, [])
                    address_from = int(base_addr, 0)
                    size = int(addr["size_byte"], 0)
                    address_to = address_from + size - 1

                    addr_entry = (address_from, address_to)

                    if isNotAligned(address_from):
                        log.error(
                            "Address bases must be aligned to 0x%x blocks. "
                            "Check the config. Addr(0x%x - 0x%x)."
                            % (MIN_DEVICE_SPACING, addr_entry[0], addr_entry[1]))
                        raise SystemExit("Base alignment error occurred")

                    if checkBaseSizeOverlap(address_from, size):
                        log.error(
                            "Size mask and base address are overlapping. "
                            " Check the config. Addr(0x%x - 0x%x)"
                            % (addr_entry[0], addr_entry[1]))
                        raise SystemExit("Base/size overlapping error occurred")

                    if checkAddressOverlap(addr_entry, addr_range):
                        log.error(
                            "Address is overlapping. Check the config. Addr(0x%x - 0x%x). "
                            % (addr_entry[0], addr_entry[1]))
                        raise SystemExit("Address overlapping error occurred")

                    if checkAddressSpacing(addr_entry, addr_range):
                        log.error(
                            "Address bases must be spaced at least 0x%x apart. "
                            "Check the config. Addr(0x%x - 0x%x)."
                            % (MIN_DEVICE_SPACING, addr_entry[0], addr_entry[1]))
                        raise SystemExit("Address overlapping error occurred")

                    addr_range.append(addr_entry)
                    node_addr_range = node.addr_ranges.setdefault(asid, [])
                    node_addr_range.append(addr_entry)
                    node.addr_spaces.add(asid)

        node.pipeline = False
        node.req_fifo_pass = False
        node.rsp_fifo_pass = False

        if isinstance(node, Device) or isinstance(node, Host):
            node.pipeline = nodeobj.get("pipeline", False)
            node.req_fifo_pass = nodeobj.get("req_fifo_pass", False)
            node.rsp_fifo_pass = nodeobj.get("rsp_fifo_pass", False)

        xbar.nodes.append(node)

    # Edge
    for host in obj["connections"].keys():
        # host: [device]
        for device in obj["connections"][host]:
            xbar.connect_nodes(host.lower(), device.lower())

    return xbar


def validate_hjson(obj: Dict[Any, Any]) -> bool:
    """Check well-formedness of obj as a parsed hjson crossbar.

    Return True if well-formed and False otherwise. This may modify obj.
    """
    if "type" not in obj:
        obj["type"] = "xbar"
    if "name" not in obj:
        log.error("Component has no name. Aborting.")
        return False

    component = obj["name"]
    error = check_keys(obj, root, component)

    if error > 0:
        log.error("{} has top level error. Aborting".format(component))
        return False

    return True
